TY - JOUR
T1 - Vegetation texture as an approach to community structure
T2 - community- level convergence in a New Zealand temperate rainforest
AU - Smith, B.
AU - Moore, S. H.
AU - Grove, P. B.
AU - Harris, N. S.
AU - Mann, S.
AU - Wilson, J. B.
PY - 1994
Y1 - 1994
N2 - Functional convergence of different communities in similar environments would be expected as an outcome of the operation of "assembly rules'. At an ecological level, competitive exclusion would restrict the co-occurrence of species with similar niches. Repetition of competitive sorting on an evolutionary time scale might lead to character displacement. Either process would ultimately lead to species niches being more regularly arranged in ecological factor space than expected on a random basis with the consequence that the niche structure of different communities in similar environments would converge. The authors assessed the applicability of this model of community structure by comparing vegetation between study sites spaced in altitude 20m apart along a continuous gradient in South Westland low-altitude conifer/broad-leaved forest, with respect to seven varieties of vegetation texture primarily concerning the morphology of the photosynthetic unit. Significant convergence between adjacent sites was found in all variates when species weighted either by percentage cover or cover rank were used to calculate site texture means, but convergence was less pronounced among groups of five or 10 consecutive sites. Significant divergence occurred at the five-site level (three variates) using cover rank as a weighting factor and at the two-, five-, and 10-site levels (five variates) when no weighting factor was used. Overall, divergence was more pronounced among sets of sites spanning a wider range in altitude, which seemed consistent with the presence of an environmental gradient along the transect, although a DCA ordination of site floristics failed to reveal a simple altitudinal trend. -from Authors
AB - Functional convergence of different communities in similar environments would be expected as an outcome of the operation of "assembly rules'. At an ecological level, competitive exclusion would restrict the co-occurrence of species with similar niches. Repetition of competitive sorting on an evolutionary time scale might lead to character displacement. Either process would ultimately lead to species niches being more regularly arranged in ecological factor space than expected on a random basis with the consequence that the niche structure of different communities in similar environments would converge. The authors assessed the applicability of this model of community structure by comparing vegetation between study sites spaced in altitude 20m apart along a continuous gradient in South Westland low-altitude conifer/broad-leaved forest, with respect to seven varieties of vegetation texture primarily concerning the morphology of the photosynthetic unit. Significant convergence between adjacent sites was found in all variates when species weighted either by percentage cover or cover rank were used to calculate site texture means, but convergence was less pronounced among groups of five or 10 consecutive sites. Significant divergence occurred at the five-site level (three variates) using cover rank as a weighting factor and at the two-, five-, and 10-site levels (five variates) when no weighting factor was used. Overall, divergence was more pronounced among sets of sites spanning a wider range in altitude, which seemed consistent with the presence of an environmental gradient along the transect, although a DCA ordination of site floristics failed to reveal a simple altitudinal trend. -from Authors
UR - http://www.scopus.com/inward/record.url?scp=0028554241&partnerID=8YFLogxK
M3 - Article
AN - SCOPUS:0028554241
SN - 0110-6465
VL - 18
SP - 41
EP - 50
JO - New Zealand Journal of Ecology
JF - New Zealand Journal of Ecology
IS - 1
ER -